Electron discharge device



April 21, 1953 H mm. PARKER 3 ELECTRON DISCHARGE DEVICE Filed June 24, 1950 4 Sheets-Sheet l April 1953 w. N. PARKER 2,636,141

ELECTRON DISCHARGE DEVICE.

Filed June 24 1950 4 Sheets- Sheet 2 Wm @M RNEY April 21, 1953 w. N. PARKER ELECTRON DISCHARGE DEVICE 4 Sheefcs-SheeLS Filed June 24, 1950 lllitlll ASQ\\\\\\\\\\\\\\\\N .I

April 2L 1953; w. PARKER 2,636,141 ELECTRON DISCHARGE DEVICE Filed June 24, 1950 4 Sheets-Sheet 4 INVENTOR 7 Patented Apr. 21, 1953 ELECTRON DISCHARGE DEVICE 'William N. Parker, Lancaster, Pa... assignor .to Radio(lorporationv of America, a corporation of Delaware Application June-24, 1950, Serial No. 170,097

35 Claims. (01. 313'-20) My inventiomrelates: to; electron discharge devices, more particularly though not exclusively to such devices useful-at therlower .as :well as higher radio frequencies and capable of delivering "extremely large amounts of. power. flhe provisionof adevice which will operate at radio frequenciesand deliver large amounts of useful power presents serious problems incapable of" solution. with conventional designs.

' 'Thetdissipation of heat generated during operation isoneof the most serious problems. Both thalectrodesras well asthe sealstructures require protection against excessive temperature. Intfachaserious limitation on thepower output lot-electron discharge devices'is the grid operattemperature. The grid: absorbs considerable heat energy-as a :result of electron bombardment andlelectroneollection during the positive portion of thegridradio frequency operating cycle.

Heat "dissipation from the conventionally long,

slendergrid elementsiis almostentirely due to thermal radiation :tocooler parts. This results in such a :high operating temperature that electron-emission can takeiplacefromthe grid.

1 .Heatcauses:expansionand contraction of the elements the device, thus affecti-ng spacings, alinements'andoperatingstability. The need. to dissipate ixheat from all electrodes and elements requiresstructures which with conventional designaa'dversely'affeet the electrical'characteris- 1:.

tics. .For'example, inductances, capacitances and electron transitrtimes are increased.

- Evenxwhere conventional devices have been capable-ref satisfactory operation under normal conditions short duration overloads usually re- 5.."

Suit in serious, ifynot permanent, damage. The fineygri'dcwire structures conventionally used are particularly"susceptible to damage from the heat generated. by." a grid-anode, fiash-arc. Sh r -decreasing the grid-cathode spacing, considerable improvement in efficiency is possible.

The advantagesjof reduced grid dissipation, ra-

dio frequency driving power. and anode loss which resultfrom suehreduced spacing are difficult "to, attain with conventional structures. One reason'for this is the susceptibility of the conventional. grid structure to deformation as a consequence of repeated temperature cycling.

'lriodetubes inamplifierroperation pass radio frequency-power as a result of electron acceleration'hythe field-setup during the positive cycle of the radiowfrequency input. Atthe higher frequencies this represents considerabielradio frequencypower whichis-absorbed or feed through by-the tube. This, of course, representsa, substantial loss in eihciency. Apower gainof only three or four is very often all that is attained with a trlode in a grounded grid amplifier circuit.

The provision of a screen grid may improve the efiiciency of-atubeprovidedthe screen, which ill) , power gains at the higher frequencies.

is: between the grid and, anode, can be maintained at the same radio frequency potential as the cathode. Inconventional .tetrode tubes, it becomesmore and more diflicult to maintain the screen grid and cathodeat the same radio ire.- duency potentialas the frequency of operation is-raised. The same is true at higher'power levels. The impedance from an active point on the cathode around the by-pass circuit to. anfop.- posite point on the screen grid becomes moreand more inductive as thefrequency or the power is increased. Also interelectrode capacities cause reactive circulating currents which increase with frequency or power.

A further limitation of screen grid power tubes is set by thepermissible screen grid heat dissipation as pointed out above in the case of control grids. This is particularly true of screen. grids since they are operated. at fairly high positive direct current potential.

It is, therefore, a principal object of my inve tion to provide an improved electron discharge device particularlyuseful as an amplifier-Jamel which delivers large amounts of power at radio frequencies.

Another object of my invention is to provide an electron discharge device having short leads and accurately maintained close spacings yetcapable of largecontinuous power outputs. at the higher frequenciesand; in which efiicient cooling is obtained; and in which interelectrode and lead. capacitances and inductances are maintained at very low values.

Another object is the provision .ofan. electron discharge, device. having a rugged control grid or screen grid capable of extremely high average dissipation and of withstanding even higher shortdurationoverloads.

Yetanother object is the provision ofanelem tron discharge device. having close spacings which are accurately maintained and inwhich the effects of temperature cycling are. eliminated.

.A further object is the provision of an. electron discharge device characterized by high Another object is the provision of an electron discharge device in which the screen grid is maintained effectively at the radio frequencypoten tial of the cathode at even the high frequencies. A stillfurther object of my invention'issto provide means for'lfluid cooling of grid electrodes, including control and screen grids. J Yet another object'ofmy invention is to provide novel and improved'grid electrodes including control and screen grids resulting in improved characteristicsand efiiciencies.

Still another object is the provision of an electron discharge. device in which feed back orcoupling between the input and output circuits with 'in the.devicezis-substantially minimized.

Briefly, an electron discharge device made in accordance with my invention includes electrodes or elements having projections which extend parallel to the electron paths. The projections are preferably substantially coextensive with the active portions of the electrodes and supportedby a metal member. Both the metal member and the projections may be directly fluid cooled.

The novel features which I believe to be characteristic of my invention are set forth in the appended claims. The invention itself will best be understood by reference to the following de- Y Figure 4 is a longitudinal sectional view thereof partially broken away for convenience;

Figures 5-10 are sectional views of electrodes or elements which may be employed with my invention;

Figure 11 is a sectional view of a construction by means of which additional cooling may be had;

Figure 12 is a perspective View partially broken away of another form of electrode;

Figure 13 is a fragmentary sectional view of the tetrode shown in Figure 2;

Figures 14 and 15 are fragmentary sectional views of electrode arrangements which may be employed with my invention; and

Figure 16 is a fragmentary perspective view of another form of electrode and support which may be employed with my invention.

For the purpose of illustration, my invention will be described in connection with triode and tetrode type electron discharge devices. However, it should be understood that it is not limited to the particular devices shown. As will be ap-'- parent, certain features of the illustrative 'devices are described and claimed in my copending joint application with L. P. Garner and W. E. Harbaugh, filed March 17, 1949, Serial No. 81,932 and which is assigned to the same assignee as my present application. Details of construction which are common to both will not be described in detail here in the interest of brevity and clarity except where necessary for a complete understanding of my present invention.

Referring now to the drawing and to Figures 1 and 2 in particular, it is seen that electron discharge device 28 is internally cooled as by water. Water cooled supporting conductors 23, 24 are mechanically and conductively connected to the electron emitter or cathode elements 2| at the ends thereof as will be pointed out. Water particopious source of electrons across tocollector or anode 22. As pointed out in said copending application the corners of lands 2! form a converging electric field at the surface of each of the cathode elements which has a focusing efiect upon the electrons.

For further affecting the flow of electrons, I provide meanson supporting conductor 24 and which extend in the region between the cathode and-anode. I preferably utilize members substantially T-shaped in cross section supported in slots 28 formed intermediate slots 26;;As'in'1Figure 1, these may be control electrode or gridlelements 3| having projections or legs 32 seated in slots 28. Projections or legs 32 are insulated from supporting conductor 24 in order that control electrode elements 3| may be'operated at a direct current potential different from that'of com dllCtOr 24.' I. 1 1' i;

I preferably form elements 3| and conductor 24 of copper or other good. electrical 'andh'eat conducting material which maybe formed into the desired shapes. Insulation 33 is made of thin sheets of mica or other material-having suitable electrical and heat conducting properties, suitable for use in vacuum and which can withstand the high temperatures at which device 20 is processed. For example, I may use a glass or glaze which wets and seals to copper and has a good thermal expansion match with copper. 1

As is-clearly apparent from Figures 3' andj4 wherein is shown a tetrode similar in many re* spect's to device 20, cathode elements 2|; anode 22, supporting conductors 23, 24 and grid elements 3| are elongated. Grid elements. 3| throughout theactive electron region are in good heat exchange relation with supporting c0nduc=- tor 24; Heat dissipation from the grid elements instead of by radiation or conduction axially, is effected mainly by conduction along projections 32 through insulation 33 to the cooled metal of conductor 24. This construction makes it possible for elements 3| to dissipate a substantially great amount of power without appreciable heating and'permits larger currents than heretofore possible to be drawn from cathode elements 2|.

From Figure 13 it will be seen that Ihave pro-'- vided means for affecting the electron'stream's between cathode elements 2| and anode .22 supported on supporting-conductor 24. in the form of screen grid elements 34. Screen" grid elements 34 are also preferably T-shaped in cross section and have a projection or leg' seated in slots 28. In addition to providing a heat conduction path along the entire active axial length of elements 34, insulation 33 also forms a by -pass condenser for the circulating currents of the output circuit. This serves to maintain screen-grid elements 34 and cathode elements 2| at the same radio frequency potentials as will be seen. Control grid elements 35 are similar to the grid elements of said copending application and, as will be more fully pointed out, are similarly mounted.

Referring now to Figures 3 and 4 electron'discharge device 36 is an internally water cooled beam power tetrode having a demountable evacu ated envelope as shown. Each of the cathode elements 2|, as in said copending application, is supported adjacent its upper end by a flexible support means indicated generally at 3'! supported from central supporting atta n:

conductor 28'. "supportingrsconductor 2311s connected at its lowerend to a'copperidiaphragm 3B lay-means ofwhichr itis; connected electrically to terminal ring39; -.i"Ih'e lower or other end of *each tcathode selement' z I is mounted ring 40 brazedto support:- ing. conductor just below the lower'eenduofuthe beam former array. Supportizur CQHdUCtOI'IWZ" i coaxial and concentric with supporting conductor 23 and has a lower portion of increased diameter; "Supporting conductor 24 lis-connected to terminal ring-41': and below the ring forms part of theexteriorof the tube. As shown'mostclearly Figure 3, "an inlet'86 and outletLBlficommunieating witlropposite "sides of partition 2-5 are formed" in the exterior portion of conductor "24. Aspreviously pointed out in connection with Figures'lrand 2 conductor 24,. in the active electron region of tube fldhas-a' pluralityof grooves or slots ZG formed therein through which each of cathode elements 21 extends? I V It should be noted;thatithe'supportingconducare 2 3; 2" l are rigidly connected by' a mechanically strong insulating and hermetic seal indicated g enerallyatez. 5

- 'Insiilated-rrom and supported'oncentral conductor 23-is aha-t shaped support member dil havinga 'peripheral' fiange' at its lower extremity with slots and centering "or locating V notches formed therein. There-is one sl'otfor each controlgrid element 35 of which thereare'twofor eachca'thode'element 2 I as is apparent'from Figlife 13. Grid 'elements "35 each hook'into grid support member ii-and areaccuratelypositioned byimeansof the slots and Vnotches. Adjacent v thcirlower'enda'each grid'element 35 ishooke'd lntoaseparate flexible support means 44 which in turn are supported-from terminali ring #5. Flexible support means 3'] and l l,'asdescribedin detail and claimed in the 'copending' application -f Each ofthe elongatedT-shapedscreen "grid elements extendinslots'fl and,' as pointed out, is conductively insulated from thewalls of theslots .by thin insulation33. The heads or cross ar'msl of the T-shaped members 34 extend axially beyond projections orl'eg's 8'5 andiiorm extensions 46, 41 (Figureell Eachof the lower extensions 46 are connectedbybolts to annular conductive support member which, in turn,v is connected to terminal ring 52] which" together form thelead-in for thescreengri'd. QA'fshieIdWih the form of an apertured annular ringjlis also connected tolmember .49 by: bolts- 46.- and provides additional shielding between theinput out: put circuits at that region.

- [Upper extensions 4.? aresboltedltoa cup-shaped shield member .5 21 having. an outwardly; turned peripheral flange. Shield memberefiz completes the shielding which, as is seen,, provides complete isolation between the input and: output circuits inelectrondischargevdevice.36.

Astis apparentnirom Figured, anode 'z lzls' -reentrant and. has aturned'back portion 2211: joined toflconducti're support 53 Support-$ 53 is coninecte d tolan'o'de terminal ring 54 which together remnants for the anode. AtLits uppergend 1 uppa-a153, as'.' in said copending A joint application, is connected toheader 55 (Figure 3) which is inlturn connected tolwater partition or sleeve Anode M150 eesieaieeeeeetewl l supporting zconductorscza; 24',-1:and has its inner endv'closedzbycend"wall 56.

The triode indicated generally at 20 (Figure :1) is similar ln construction: to the tetrode just described and indicated generally byinumeral ,35; In'the former, elements correspondingto grids together: with the attendant mounttstructure arenotpresent. '=I'h11s,1ln1tube Z6, thegrid rsupe porting structure above 'thecflexible cathode sup. port means-3'! is omitted. 'Grld-elements: Bleach have upper and lower :axial extensions corresponding to extensions 146, 41.. The upper extensions of grid elementsil are connected to'a shield similar to cup-shaped shield: 52 The flexiblegricl support 44 of tube 36 is also omitted and instead the lower grid element extensionsware connected to terminal'ring 45. Terminal. ring and its seal is also: omitted and a single insulating glass spool is provided between terminals 45 and instead of the'two shown in Figure 4", It is believed thatfrom the foregoing comparisonof tubes 20 and '86, the complete structure cr tube zo isclearlybrought out and that's/separa'te drawing'showing such "a tube is unnecessary. inventionrea-dily' iends itself to-a wide variety of'forms, some-of which are shown in the drawing, each. having its own mechanical and electrical characteristics. "In'Figure 5 are shown grid elements having Vheads 51 with rounded apices while in-Figure 6 theheads of the grid elements areomitted entirely. In the latter case projections Ea-function asthegrid elements'and give extremely low gri d absorption. However; this 'form requires relativ'ely high driving voltage for operation as a power converter. I

In Figure 7, projection or legfifi is tapered and with a reversely taperedslot or grooveservesto key the grid elements into supporting conductor "'51 V V 'InFigure-il; projections'or legs EZ-are v shaped and provide a'lnetten heat conduction path" than Tubes 69 need notjnecessarily be integral with projections 68 but maylconveniently be'in the form of. conduitsconnected thereto by any'suitable good heat conducting solder. Pairs of conduits fistmayvbe joinedat their upper ends While thelowerends are connected to aninlet and'an outlet the lower portion of supporting conductor' 'l'fl which as inthe case of supporting conductor 24,.forms aportion of the external envelope of .vthedevice. Here the grid elements have heads H which are trapezoidal in cross section. I

Instead of connecting conduits 69 in. pairs each conduit may be closed at its upper endiand include within it a second conduit of smaller diameter (not shown) ope-net its upper end.

The lowerlends of all the inner conduits are then brought to a. single inlet While the lower ends of conduits $9 arethen all brought toa single ou t-c. I I

' 'It" is to beu'nderstbod that the inletsare con nected to sources of fluid coolant such as water under pressure. '1 i" IWhere a considerable difference in temperature may exist between the heads or cross arms o'futhe elements and'the projections or legs,-I .provide each element with a plurality of projections or legs 12 of relatively short axial length separated by narrow gaps or slits 13. This is not readily practiced in connection with the fluid cooled projections 6!! of Figure 11 and I there, when necessary, provide narrow slits along the head or cross arm portion. .zAs shown in Figure 14, I may also provide pro- .jections 16 which are integral with or conductively connected to the supporting conductor [4 which corresponds to conductor 24. Elements lfunction as the screen grid and are U -shaped in cross section to receiveprojections T6. Insulation 33 serves as direct current insulation between elements l5 and conductor I l.

-- Themeans for affecting the electron stream .in addition to the control and screen electrodes described, includes other electrodes or elements for affecting the electron streams throughthe action of the electric field created by them. For example, another, typeof element is shown in Figure 15 where a spacecharge electrode or grid "is provided by extensions H. A positive polarity :electricfield gradient isformed at the emitting surface of cathodes 2! without the potential of control grid elements 35 going positive. Such a ;tube.passes the high peak plate currents re.-

quired for efiicienthigh power output with zero control grid current and electronic driving power.

In Figure 16 is seen still another form of construction. Here, the supporting conductor, which corresponds toconductor 24, is made up. of a in a known manner.

from-laminations i8, i9 and are connected to element-3! which may function as an electrode .or electrostatic element.

r--AdditiOI1El1 cooling may be readily provided when desired by increasing the area of the heat exchange interface. This may-readily be done ,by increasing the numberof projections, either on the electrode or the supporting conductor which are then in interleaved relation. 1

.IEl'ectron discharge devices made in accordance with my invention maintain close efiective spacings. .In connection with a triode tube the close "effective gridecathode spacing makes possible higher output and efiiciency with lower driving power. The provision of relatively massive grid electrode. elements which are conductively cooled 'makesf possible an exceptionally stable tube. The capacitance developed between the grid elejments and the beam former or supporting conductor 24 forms an appreciable portion of the grid-cathode tank circuit capacitance. "Since this' is located right at the grid elements, high frequency parasitic oscillations are minimized.

Such a device as tetrode tube 36 makes pos- "sible high power gains in amplifier applications since the screen grid elements are more effectively bypassed to the cathode than was heretofore thought possible. In such a device there issubstantially no fed through power as with conventional constructions. The e'fiective conduction cooling of the screen grid elements makes possible more efficient operation. Because of the increased dissipation capability, the

anode voltage can swing lower without the increased screen grid current tending to overheat "to said cathode assembly.

the grid." .The increasedgganode voltage,,,swing means greater output andefiiciency. 3,;

AS pointed out, and particularly at; the-higher frequencies, the capacitance developedjbetween projections connected to elements 34 and supporting conductor 24 ,serves as the radio frequency by-pass between the screen .grid and cathode. All portions of each screen grid element in the active electron region of device 38 are maintained at substantially the same radio frequency voltage as supporting conductor 24. Any circulating currents which may flow between thescreen grid and conductor 24 flow radially inward; along the. surfaces of projections; 85, through insulation 33, directly to conductor 24 This radio frequency path is one of extremely low impedance. It is also apparent that the circulating currents of theinput circuittravel ,axiallyalong the-control grid elements 35 and at :an angle of ;degrees;with respect-to the output circuit currents just described. Asa re.- sult coupling between the circulating currents of output and input circuits is reduced-to a minimum.

Instead of directly heated or self-heating elements 2|; 1 may utilize an. indirectly heated cathode having a plurality of spaced. electron emission surfaces as shown and described in the copending application of L. P. Garner. Said Garner-application is assigned to the same assignee as my present application and was filed simultaneously therewith. As shown andfldescribed in said copending application, a plurality of channeled support members are provided each ofwhich may be connectedto. supporting conductor 24,-preferably inslots 26. Emission material maybe readilycoated on a surface of said support members and a heater provided in each of the-channels formed between the supporting-conductor 24 .and each of the support members.

'From theforegoing,v it is apparent that electron discharge devices constructed inv accordance with my invention are capable of operation at greater efficiency at the loweras well as higher frequencies .as well as handling considerably higher power with'greater gain than devices heretofore in use. Furthermore, my invention .is subject towide variation and modification without j departing from the scope thereof. Therefore, it is intended to cover all such m odifscope of the appended claims. a

a Reference is made to copending application 170,231disclosing subject matter which appears fications and variations as come within the in this application.

ments, the other of said electrodes andeach of said elements having an elongated active portion,

and insulative means individually connecting substantially the entire active length of each of said elements to substantially the entire active length of said other electrode. Q

2. An electron device, comprising a cathode assembly having a plurality of spaced electron emission surfaces, an anode "spaced from said vcathodaassembly, an electrode comprisingan array of elements in the region between said. emission surfaces and said anode and, dielec tric means individually connecting each of said elements along the entire active portion thereof 9T aelectron zdischargerlevicewcomprisingta supporting. :conductorrran relectron :remitterzsuns ported-cbyrisaid :supporting conductonian'd Eclecttricallynconnected: thereto',": a :collectomforore-roeiviugzelectrons spaced fromi said: electron temits tenra controlqelectrodevcomprising:at leastmne elongated elementiibetweenaisaidrelectron emitter trically; insulated: along substantially-witsr'entire,

active length from": said:supporting:conductor as; toicdire'ct potentials hut; being; physically: in contact therewith in good heat exchangegrelation-e ship. ,z'fl

:eleotron .IdiSOhZI'gE, device, :comprisingaa supportingrvconductor; means afor :coolingnsaid conductorra cathode:supported bmsaidxsupporte in'g conductorzand conductivelyzeonnectedthereu toga-an; anode, means :for a supporting said" :anode inaspacedsrelation with respectx tovsaidicathode, an 1 elongated: electrodez .extendingii in vthe space between the; cathode and: anode;aandzxdielectric means on said elongatednelectrode :alongvsuhxstantially the.:entire:activelength.thereoftbetween it and said supporting conductor, said'lastvm'en, tioned r-means affording;the electrode :a good heat exchange. :relationship: along: substantially? 3 its entire active length with said supporting iGOIldllC+ tomand :electrically: insulating: it itherefromnasato direct potentials. 1

- 5, a An- .electron discharge; device,,comprising conductive-support means having to. plurality :of slots 1 formed thereinea plurality ,of cathodeele; ments one "extending; in alternate-.izslotszot. said support means.and=conductivelyconnectedthere;

to,-.and means for afiiecting the iflow -of electrons front. said i cathode elements .;and 1 extending in the. iremaining: slots x-electrically insulated" from said'ifirst: mentioned. means as: to direct: current potentials l -6.-Anelectron discharge device; ;comprising:.sa plurality of cathode elements, =.a supporting icon.- ductor having a plurality ofslots formed.-

n the surface thereoL-ieach. :ofi said cathodeeelements extending in,:alternate slots, -andua pluralityu pf elements of substantiallyv T-shaped: crosssseetion respectively supported with dielectric materialiin the alternate SIOtSzbGSWGGII the :slots iocoupied hy theflcathodeielements.:;. t t

7. electron-discharge deviceaaslin;:claimwfi and: means'.:,for" cooling .said supportingiicondum tQIZ: y p 8. eAntelectron t discharge; device, :asxuin: claim: E6 in which each of :said elements A is asupportednin a respectivaslotubya portion otatheaelement scarrespondlngltoizthe Iegfi of its tfreshaped :cross sectionwith anotherrportioni which corresponds toothe. :head.i of [said crossa sectiom i'extending beyond said cathode elements in a directionaway from thesupporting conductor.

9;. An electron; discharge device; comprising; :a supporting conductorzlhaving :a. plurality: ofoslots formed "thereinaiai plu'rality n'ofr.spaced: cathode elementszlea-ch .of which: .extendsztin lair alternate oneiot saidislotsna pluralityi of: electrodes 5 each having a-rprojectiornextending iniith'e remaining alternate slots .of: said" onesupporting conductor; means insulating'isaidi projectionsftromisaid: sup; porting conductorrpasi-toi direct: potential;- said cathodeiaelements being: rconduotiv'elyi:connected to said supporting conductor, :andimeans forscools ingnsaid: supporting. conductor; said; insulating means. connecting saidiprojections; anclzsa'idisups porting conductor in: goodnheat exchangarrelae tionshi'p and Iorming v9, radio nirequcncyipyapass herehe neena i v .1

accents said one isupportingeconductor, saidn head- 1 pore tions further extending axially-beyond saidcath-e odezelements:cndformingextensions, a shield-em closing gone and l -Qf'- 1 said" i cathode elements wand connected to-theIeXtensions .formedwan oneaend ,ofzs'saidrielon gated elements, :and leadein :means connected-to saidelongated-elemental 1 L .:.An :fielectron discharge: device, ecomprising an evacuated envelope-a pair ofusupportingicon-i ductorsin spaced relationandiextendingithtough said envelope; one of said supportingveonduo tors having a plurality of 310138 tformed :thereiznga plurality: ;of elongatedspaced cathode "elements each extending :an alternate .one of said. slots and conductively connected-l te: saidtsupporting conductors, arr anode. in-ispacedtrelation :to said cathode: elements, means :for? supilorting -gsaid anode including a terminal a plurality 0ft elem gated elements each having .a head and prcdcc tion portion; said projection portions i extending in the remaining alternate slots. meansiinsulatiing @said projection tportions from the malls. of said: slots and" torminga radioi'requency byi-pass therebetween; .said; head portions. extending the space between said" cathode elements iandisaid anode said .ihead- 4 portions :mI further 1 extending axially beyond saidnprojection portionszm shield connected to said; elongated elementsadjacent one :end of said. head portions and enclosing one end! of saidlcathode ielements land a terminal connected to the :othen ends ofisaidiheadportions and\ sealed-.- through :said vacuum envelope, 1,

12. An electron discharge; devioechaving a gas tight envelopecomprisinga pair oftcoax-ial concentric tubular: supporting oconductors: :eachmt which forms a portion=.of-. said; gas tightrenvelope. onexof said supporting: conduotorshavinea :plwralitynof "slotsformed in a surface. thereof within said gas-tight envelope,- means joining said. sup-f porting-conductors in insulatedigasrtight'irelation at one endlthereof, means forcoolingntheopposcd surfaces vof: said supporting l ;.conductors; a =plwrality of elongated spaced cathode elementsieach extending in analternatemne ot'said: slotsj-end conductively connected-to each of saidisupportg ing conductors; an :anode, means :for supporting and cooling said. ianode said anode formingr a. portion: oftsaid gasitight envelope; 2. plurality-wot elongated-tT-shaped elements-ihavingrdiead and projection portions, :said.projectionvportionsiex tending a ,in-. the remaining aalternateqslots :ofssaidonesuphorting conductor, :means insulating :said proj ectioniportions from said tone supportingicom ducte -and joiningdthe same in .good heats ext change; "relation, i said "headmportions' extending ,v axiallytbeyondsaid projectionpoi'tions andiforme ing extensions, and a terminalwconnectedz-to the extensions :at one lend: of said headportions and sea-led: through said easntight. envelope, 2

1'33: Amreleotron discharge:idevicep-fcomprisinl conductiversupport ;.means.havina1a pliiralitwotslots formed therein with lands therebetween, a

plurality of cathode elements one extending in alternate slots of said support means and con- 'ductively connected thereto, a plurality of grid elements each of which being positioned opposite one of said lands, means for supporting said grid elements, and means for affecting'the flow of "electrons from said cathode elements and having a portion thereof extending in each of the remaining slots and insulated therefrom as to direct potentials. 14. An electron discharge device, comprising a supporting conductor having a plurality of slots with lands therebetween formed therein, a plu rality of spaced elongated cathode elements each extending in alternate slots and conductively connected to said supporting conductor, a plurality of control electrode elements, means supporting each of said control electrode elements spaced from and opposite each of said lands, and a plurality of screen grid elements each having head'and projection portions, said head portions extending on the side of said control electrode elements away from said cathode elements, said projection portions extending in the remaining slots in said supporting conductor and dielectric means joining said projection portions to said supporting conductor and forming a radio frequency by-pass therebetween.

.15. An electron discharge device, comprising a supporting conductor having a plurality of slots with lands therebetween formed therein, a plurality of spaced elongated cathode elements extending in alternate slots and conductively connected to said supporting conductor, an anode spaced from said cathode elements, a plurality of elongated control grid elements, means for supporting each of said control grid elements in the space between said cathode elements and said anode and opposite said lands, a plurality of elongated screen grid elements having head and projection portions, each of said projection portions extending in each of the remaining alternate slots, means insulating said projection portions from the walls of said slots and forming a radio frequency by-pass, and lead-in means connected to said head portions. 1

16. An electron discharge device, comprising a "supporting conductor having a plurality of slots formed therein with lands therebetween, a plurality of spaced cathode elements each extending in-one of said slots, a projection on each of said lands and extending outwardly therefrom, and means for aifecting the fiow of electrons from said cathode elements physically connected to each of said projections but electrically insulated therefrom asto direct potentials. 17. An electron discharge device, comprising a supporting conductor having a plurality of slots formed therein, a plurality of elongated spaced cathode elements each extending in an alternate one of said slots and conductively connected to said supporting conductor, a plurality of elongated substantially T-shaped elements each having a head and projection portion, a cooling fluid conduit'connected to each of said projection portions, each of said projection portions and conduits extending in the remaining alternate slots.

l8. An electron discharge device, comprising a supporting conductor having a plurality of slots formed therein, a plurality of spaced elongated cathode elements each extending in alternate slots and conductively connected to said supporting conductor, an elongated anode spaced from said cathode elements, means forsupporting said rality of spaced elongated cathode elements each extending in one of said slots and conductively connected to said supporting conductor, an anode spaced from said cathode elements, means for supporting said anode, and a plurality of ele-' ments for affecting the flow of electrons from said cathode elements extending in the space between said cathode elements and said anode, and means insulatingly connecting each of said elements to one of said lands along substantially its entire active length. A

, 20. An electron device, comprising a conductive electrode supporting structure, an annular array of spaced-apart directly heated emissive "filaments supported thereon, each filament being individually connected to the structure at its two ends, an annular array of spaced-apart electrode elements carried on said structure and positioned in cooperative relationship with the array of filaments to control the flow of electrons therefrom, each element of the last-mentioned array having a portion which extends between a pair of said filaments to a respective portion of the support structure, and dielectric means connecting each of said elements to the portion of the supporting structure to which it extends, said supporting structure including a tubular metallic member, said filaments and said elements extending in directions which are parallel to the axis of said tubular member and adjacent one surface thereof, the opposite surface of said tubular member being adjusted to contact a liquid coolant.

. '21. An electron device, comprising at least two electrodes in spaced relation, one of said electrodes including an array of spaced apart elements, the other 'of said electrodes and each of said elements having an elongated active portion, and dielectric means individually connected along substantially the entire active length of each of said elements and to said other electrode along substantially the entire active length of said other electrode, said dielectric means constituting an electrical insulator as to direct current potentials.

22. An electron device, comprising a source'of electrons, an output electrode spaced from said source, a first electrode means having an active portion intermediate said source and said output electrode and having a low impedance electrical coupling with said source along substantially the entire active portionthereof, and a electrode spaced from said source, a first electrodemeans having an elongated active portion intermediate said source and said output 'elece I trode and having a low impedance electrical coupling with said source along substantially the entire active length thereof, a second electrode means having an elongated active portion intermediate said first electrode means and said output electrode, and elongated insulative means insulatively connecting said first electrode means to said second electrode means along substantially the entire active length thereof.

24. An electron device, comprising a source of electrons, an output electrode spaced from said source, means supporting said source and having a low impedance electrical coupling with said source, another electrode having an active por tion intermediate said source and said output electrode, and electrically insulative thermally conductive means connected to said another elec trode substantially along the entire active portion of said another electrode and to said firstmentioned means.

25. An electron device, comprising a source of electrons, means supporting said source and including a conductive member having a low irnpedance electrical coupling with said source, an output electrode spaced from said source, annother electrode having an active portion intermediate said source and said output electrode, and electrically insulative thermally conductive means connected to said another electrode along substantially the entire active portion of said another electrode and to said conductive member.

26. An electron device, comprising a source of electrons, means supporting said source and including of conductive member having a low impedance electrical coupling with said source, an output electrode spaced from said source, another electrode having an active portion intermediate said source and said output electrode, and dielectric thermally conductive means connected to said another electrode along substantially the entire active portion of said another electrode and to said conductive member and maintaining the same in good heat exchange relationship, said last-mentioned means electrically insulating said other electrode from said conductive member as to direct current potentials.

27. An electron device, comprising a source of electrons, conductive means supporting said source and having a low impedance electrical coupling with said source, an output electrode spaced from said source, another electrode having an active portion intermediate said source and said output electrode, capacitive means connected to said another electrode, along substantially the entire active portion of said another electrode and to said first mentioned means, said. last mentioned means forming a good capacitive connection with respect to alternating current potentials and an insulating connection as to direct current potentials.

28. An electron device, comprising a source of electrons, means supporting said source and including a conductive member connected to said source, an output electrode spaced from said source, another electrode having an active portion intermediate said source and said output electrode, dielectric thermally conductive means connected to said another electrode along substantially the entire active portion of said another electrode and to said conductive member, said last mentioned means forming a good capacitive connection with respect to alternating current potentials and an insulating connection as to direct current potentials, and means for cooling said conductive member.

29. An electron device, comprising a source of electrons, an output electrode spaced from said source, means supporting said source and including a first electrode means having an active portion intermediate said source and said output electrode, a second electrode means intermediate said first electrode means and said output electrode, a third electrode means intermediate said second electrode means and said output electrode, and dielectric thermally conductive means connected between said third electrode means and to said first electrode means along substantially the entire active portion thereof, said last mentioned means insulating said first and third electrode means as to direct current potentials and maintaining the same in good heat exchange relationship.

30. An electron device as described in claim 29 wherein said third electrode means substan tially shields said second electrode means.

31. An electron device, comprising a source of electrons, an output electrode spaced from said source, means supporting said source, a control electrode intermediate said source and said output electrode, another electrode intermediate said control electrode and said output electrode, and dielectric means connected to said first mentioned means and said another electrode along substantially the entire active portion of said another electrode.

32. An electron device as claimed in claim 31 wherein said another electrode substantially shields said control electrode from said output electrode.

33. An electron device, comprising a source of electrons, an output electrode spaced from said source, means supporting said source and including a conductive member having a low impedance coupling with said source, a control electrode intermediate said source and said output electrode, another electrode intermediate said control electrode and said output electrode, and dielectric means connected to said conductive member and to said another electrode along substantially the entire active portion of said another electrode, said last mentioned means electrically insulating said another electrode from said conductive member as to direct current potentials.

34. An electron device as described in claim 33 wherein said last mentioned means is thermally conductive and maintains said another electrode and said conductive member in good heat exchange relationship.

- 35. An electron device as described in claim 34 wherein said means supporting said source includes means for cooling said conductive member.

WILLIAM N. PARKER.

References Cited in the file of this patent UNITED STATES PATENTS- Number Name Date 1,944,190 Mouromtseff Jan. 23, 1934 1,961,192 Bowles June 5, 1934 2,380,502 Clark et al. July 31, 1945 2,419,485 Desch et a1 Apr. 22, 1947 

